BACKGROUND OF THE INVENTION1. Field of the Invention
The present invention concerns a backflash interrupter device for in-line placement in a run of pipe, duct, or the like for preventing a pressure wave and any subsequent flame front traveling along the run from passing beyond the device. More particularly, the invention is concerned with an apparatus having structure for venting the pipe run in the event of excess pressure in order to interrupt the progress of a pressure wave any subsequent flame front traveling therealong thereby preventing consequent damage to equipment connected to the run.
2. Background of the Prior Art
Flammable or explosive materials in the form of vapors or fluidized particles, for example, are often conveyed by runs of pipe, duct, or the like which may interconnect various pieces of equipment If ignition of the material occurs, a pressure wave and potentially subsequent flame front may spread by way of the interconnecting pipes or duct work to other pieces of equipment, thereby magnifying the risk of injury to personnel or equipment damage. In view of this problem, pieces of equipment handling explosive or flammable material are often equipped with relief valves, relief vents, rupture discs, relief panels, and so forth which require that the equipment be designed with these features, or provided with such as a retrofit.
These prior art solutions, if properly designed, can effectively limit the damage to a particular piece of equipment but are not designed or intended to protect the pipeline or duct work itself, or to prevent passage of the pressure wave or flame front through the run of pipe or duct. That is to say, the prior art devices are designed to protect the specific pieces of equipment to which they are attached, but are not designed to protect the pipeline or duct work or prevent spread of the ignition effects therethrough.
SUMMARY OF THE INVENTIONThe present invention solves the prior art problems as outlined above. That is to say, the invention hereof provides a device allowing in-line placement in a run of pipe, duct, or the like which prevents a pressure wave and any subsequent flame front traveling along the run from passing beyond the device into adjacent portions of the run and equipment connected thereto.
The preferred backflash interrupter device of the present invention broadly includes chamber structure defining an enclosed chamber and including a pressure responsive vent cap for opening the chamber for exterior venting upon the occurrence of a predetermined level of pressure in the chamber. Respective first and second fluid conducting members are coupled with the chamber in a non-aligned relationship thereat in order to prevent direct in-line fluid flow between the members. The distal ends of the connecting members are configured for in-line connection in the run of pipe, duct, or the like between adjacent portions of the run.
In one preferred embodiment of the invention, the conducting members are coupled with the chamber structure in a concentric relationship. In another embodiment, the conducting members are coupled with the chamber in a spaced-apart relation ship, and the chamber end of at least one of the members is equipped with a closure device which automatically closes that member end when the chamber is vented. Other preferred aspects are discussed further hereinbelow.
BRIEF DESCRIPTION OF THE DRAWING FIGURESFIG. 1 illustrates one embodiment of the preferred interrupter device installed in-line in a run of pipe interconnecting two pieces of equipment as an exemplary usage;
FIG. 2 is a partial sectional view of the interrupter device of FIG. 1;
FIG. 3 is a partial sectional view of a second embodiment of the preferred device;
FIG. 4 is a partial top view of the device of FIG. 3 with the top cap removed and with portions of the closure flaps cut-away for clarity of illustration; and
FIG. 5 is a partial sectional view of a third embodiment of the device illustrating a closure flap in the open position with the closed position shown in dashed lines.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTFIG. 1 illustrates one embodiment of backflash interrupter device 10 in a preferred environment of use in which device 10 is placed in-line in arun 12 of pipe interconnecting aconventional dust collector 14 anddust collection hood 16. Vacuum induced airflow fluidizes and conveys flammable or explosive dust particles fromhood 16 throughrun portion 12a, into device 10, and therefrom through run portion 12b and intodust collector 14 in the direction as shown by the arrows.
FIG. 2 illustrates a partial sectional view of the embodiment of device 10 shown in FIG. 1 which includes chamber structure orbase 18 andvent cap 20 which together define enclosedtransfer chamber 22, and which further includesinlet conductor pipe 24 andoutlet conductor pipe 26.
Chamber base 18 is in the form of a conventional open-center, slip-on pipe flange having anannular groove 28 defined inupper face 30 thereof which contains a conventional 0-ring 32 therein.
Ventcap 20 is preferably composed of stainless steel and integrally configured to include dome 34 presenting an arcuate cross-section,annular flange portion 36, and downwardly extendinglip 38 designed to fit about theupstanding face 30 ofbase 18 for centeringcap 20 thereon. As illustrated in FIG. 2, O-ring 32 provides a seal betweenbase 18 andcap 20 by engaging the lower surface offlange portion 36. In the environment of FIG. 1, the interior of device 10 and inparticular chamber 22 are under a partial vacuum which holdscap 20 in place onbase 18 with 0-ring 32 providing a seal therebetween.
Stainless steel cord 40 coupled with dome 34 also loops throughrespective bolt holes 42 inbase 18 to act as a tether.
Inlet conductor pipe 24 is preferably in the form of a conventional non-reducing 90° pipe elbow and includeschamber end 44,inlet end 46 presentingport 48, and aninlet connection flange 50 welded to inletend 46.
Outlet conductor pipe 26 is preferably in the form of a conventional reducing 90° pipe elbow and includeschamber end 52,outlet end 54 presentingport 56, andoutlet connection flange 58 welded tooutlet end 54.Chamber end 52 is placed and welded within the interior opening ofchamber base 18 as illustrated in FIG. 2.
In the preferred embodiment illustrated in FIG. 2,inlet pipe 24 presents a smaller diameter in the vicinity ofchamber end 44 than the diameter ofoutlet conductor pipe 26 in the vicinity of itschamber end 52. This allows that portion ofinlet pipe 24adjacent chamber base 18 to be located concentrically withinoutlet pipe 26.Pipes 24, 26 are placed in this relationship by cutting an appropriately sized hole inoutlet pipe 26 through whichchamber end 44 ofinlet pipe 24 is placed.Inlet pipe 24 is then welded tooutlet pipe 26 to seal the opening and holdpipes 24 and 26 in the concentric relationship illustrated.
In the preferred embodiment illustrated in FIGS. 1 and 2, backflash interrupter device 10 is sized as appropriate for the diameter ofpipe run 12. For example, if run 12 is 4" pipe, outlet andinlet ports 48,56 and associatedflanges 50,58 would also be sized for 4" withports 48,56 axially aligned withpipe run portions 12a,b as shown withbase 18 provided as a six-inch slip-on flange andoutlet pipe 26 as a six-to-four inch reducing elbow. Device 10 can be conveniently placed in-line with pipe run 12 by boltinginlet flange 50 to a matedflange 60 on the exposed end ofpipe run portion 12a, and by boltingoutlet flange 58 to a matedflange 62 on the exposed end of pipe run 12b.
The preferred design of device 10 as illustrated in the drawing figures enables convenient and economical placement in-line withpipe run 12 either as a retrofit or new installation. For example, if backflash interrupter device 10 is to be installed as a retrofit, an appropriate length ofpipe run 12 would be cut and removed and appropriately sizedconnection flanges 60,62 welded to the exposed ends of respective pipe runportions 12a,b for connection to inlet andoutlet flanges 50,58 respectively. In the case of a new installation,pipe run 12 can be originally installed with pipe runportions 12a,b appropriately flanged and spaced for reception of device 10.
In the operation of the system as illustrated in FIG. 1, fluidized dust particles collected athood 16 normally travel alongpipe run portion 12a in the direction indicated by the arrow. The fluidized particles pass through device 10 and then along pipe run portion 12b in the direction of the arrow intodust collector 14. This air flow is created by a partial vacuum induced indust collector 14 which in turn creates a partial vacuum in device 10 and pipe runportions 12a,b. This partial vacuum along with gravitational force holdsvent cap 20 in place.
Fluidized particles fromrun portion 12a enterinlet pipe 24 throughinlet end 48 and pass upwardly throughinlet chamber end 44 intochamber 22. The flow direction then reverses and passes downwardly throughoutlet chamber end 52 intooutlet conductor pipe 26 around the exterior ofinlet pipe 24 contained therein. The flow then exits throughoutlet port 56 into run portion 12b.
In the event of ignition of the dust particles contained in the fluidized flow, a pressure wave traveling at the speed-of-sound typically precedes any subsequent flame front. When the pressure wave enterschamber 22 from either direction by way of pipe runportions 12a or 12b,vent cap 20 is blown off by the pressure wave but remains tethered tochamber base 18 bycord 40. This action openschamber 22 and exposes chamber ends 44,52 of bothpipes 24, 26 for exterior venting and prevents the pressure wave from propagating along run 12 beyond device 10. Any subsequent flame front traveling along either ofpipe portions 12a or 12b also exits from device 10 by way of associatedconductor pipe 24,26. The flame front is thereby prevented from entering the other conductor pipe and the adjacent pipe run portion. In other words, withoutvent cap 20 in place to redirect the fluid flow from one conductor pipe to the other, a pressure wave or flame front entering device 10 from either direction is exteriorally vented instead of passing into the other pipe portion.
As those skilled in the art will appreciate, device 10 can be designed for operation on a pressurized system by appropriate biasing of vent cap 10. For example, by designingvent cap 20 with a heavier weight or by adding weight to it, gravitational force can be used to define the predetermined pressure at whichvent cap 20 is shifted toopen chamber 22. Other biasing alternatives might include springs or shear bolts for example.
FIGS. 3 and 4 illustrate asecond embodiment 64 of the backflash interrupter device of the present invention.Device 64 includes rectangularly-shaped, relatively flat chamber structure orbase 66 having circularly-shapedconnection openings 68, 70 defined therethrough.Device 64 also includesvent cap 72 presenting a channel-shaped cross-sectional configuration,closure structures 74,76, andconductor pipes 78,80.
Vent cap 72 integrally includes peripheral mountingflange 82 through which ventcap 72 is preferably coupled tochamber base 66 by fourshear bolts 84 designed to release at a predetermined level of pressure withinchamber 22.
Eachclosure structure 74,76 includesclosure flap 86, hinge 88shiftably coupling flap 86 tochamber base 66, biasingspring 90biasing flap 86 toward a closed position as shown in FIG. 4, and stoptab 92 coupled to the upper wall ofvent cap 72 for holdingflap 86 in the open position against the bias ofspring 90 as shown in FIG. 3.
Eachflap 86 is circularly-shaped to fit a corresponding chamber opening 68, 70 which presents a mated surface for tight closure.
In the second embodiment,conductor pipes 78,80 are preferably conventional, non-reducing, 90° pipe elbows with respective chamber ends 94,96 thereof fitted respectively inopenings 68,70 and welded in place. The respective distal ends 98,100 terminate at respective connection flanges 102,104.
Device 64 in the preferred second embodiment is configured as bi-directional from the standpoint of normal fluid flow therethrough without a designated inlet or outlet. In operation, normal fluid flow through one ofconductor pipes 78,80 enterschamber 22 wherecap 72 redirects the flow for outlet through the other conductor pipe. In the event of pressure above a predetermined level withinchamber 22,shear bolts 84release vent cap 72 to openchamber 22 thereby exposing pipe ends 94,96 for exterior venting. Asvent cap 72 shifts outwardly, stoptabs 92 also shift outwardly allowing closure flaps 86 to shift to their respective closed position overchamber openings 68,70 under the bias provided bysprings 90.
The provision ofclosure structures 74,76 ensures that any subsequent flame front emanating from one ofpipes 78,80 does not enter the other pipe. Even though the flame front is venting exteriorally away from the chamber opening leading to the other pipe, this may be insufficient to prevent ignition therein when handling some flammable materials, especially flamable vapors. Hence, closure of that chamber opening by the associated closure structure prevents ignition of the unignited material. As those skilled in the art will appreciate, a pressure wave usually precedes any flame front which allows time for closure in response to the pressure wave prior to arrival of the flame front. If it is known from which direction a flame front will likely emanate, then only one closure structure may be required for closing the appropriate chamber opening.
FIG. 5 illustrates athird embodiment 106 of the preferred backflash interrupter device. This embodiment also includes a preferred rectangularly-shapedchamber base 66 but with chamber openings 108,110 presenting a preferred square-shaped cross section, and with respective conductor pipes 112,114 also presenting square-shaped cross-sections.Device 106 also includesvent cap 116, hinge 118,valve flap 120,valve flap stop 122, andvalve flap retainer 124.
Hinge 118 shiftably couples ventcap 116 tochamber base 66 along one edge thereofadjacent conductor pipe 114. This allowsvent cap 116 to shift between the closed position as shown in solid lines in FIG. 5 to the open position shown in dashed lines.
Square-shapedvalve flap 120 is preferably an integral extension depending from one side ofvent cap 116 and extends downwardly whencap 116 is in the closed position into an appropriately definedrecess 126 along the interior surface ofconductor pipe 114.
In the event a pressure wave in excess of a predetermined level enterschamber 22 by way of conductor pipe 112,vent cap 116 shifts to the open position which shiftsvalve flap 120 to the closed position as shown in dashed lines in FIG. 5. Upon reaching the closed position,valve flap 120 and attachedvent cap 116 are prevented from further movement bystop 122 and are retained in that position byretainer 124. Any subsequent flame front from pipe 112 is thereby prevented from enteringpipe 114.
Retainer 124 is preferably in form of a relief spring coupled to the interior wall ofconnector pipe 114 on the opposite side thereof fromrecess 126. Asvalve flap 120 shifts to its closed position,retainer 124 is depressed into relatively flat engagement with the interior wall ofconnector pipe 114. Afterflap 120 reaches the closed position,retainer 124 springs back to the position shown to retainflap 120 in its closed position.
As those skilled in the art will appreciate, the present invention encompasses many variations other than those illustrated and discussed herein. For example, at a juncture of three or even more pipes or ducts, the backflash interrupter device hereof can be designed for coupling with all of the pipes or ducts at the juncture thereby providing a very economical installation. In addition, the preferred device can be configured for pipe or duct, square or round, or other shapes, as a matter of design choice. Furthermore, the device hereof can be designed to vent at a desired level of predetermined pressure.